Fiber patch panel

ABSTRACT

A system may include a housing and a patch panel located within the housing. The patch panel may include a connection plate, and a matrix of fiber connectors connected to the connection plate and arranged to receive optical fibers in a vertical direction.

BACKGROUND

A patch panel typically includes a panel of network ports thatfacilitate the interconnection of a number of cables. The patch panelpermits connectors to be connected in a horizontal manner withconnections in the front and back.

Existing patch panels have several problems. For example, existing patchpanels are bulky (i.e., take a lot of space). Patch panels are typicallyplaced in closets, where space is very limited. Also, the connectorsconnected to patch panels often get dirty and need to be cleaned.Existing patch panels make it easy to access the front connectors butvery difficult to access the back connectors. Further, the horizontalnature of the patch panels promotes fiber bending, which leads to powerloss and ultimately to signal degradation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of an exemplary fiber patch panel system;

FIG. 2 is an exemplary diagram of a front view of a patch panel depictedin FIG. 1;

FIG. 3 is an exemplary diagram of a front view of a connection platedepicted in FIG. 2;

FIGS. 4A and 4B are exemplary diagrams of a fiber connector of FIG. 2;

FIG. 5 is an exemplary diagram of a front view of the fiber connector ofFIGS. 4A and 4B;

FIGS. 6A and 6B are exemplary diagrams illustrating the seating of afiber connector on a connection plate;

FIG. 7 is an exemplary diagram of a scaleable fiber patch panel system;and

FIG. 8 is an exemplary diagram of a fiber patch panel system thatincludes a splice tray or drawer.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The following detailed description refers to the accompanying drawings.The same reference numbers in different drawings may identify the sameor similar elements. Also, the following detailed description does notlimit the invention.

Implementations described herein may provide an arrangement for a fiberpatch panel system that conserves horizontal space, manages fiberbending diameter, provides easy access to the fiber connectors, permitseasy cleaning of both ends of the optical fibers, is scaleable, and/orpermits easy installation of a splice tray or drawer.

FIG. 1 is a diagram of an exemplary fiber patch panel system 100. Fiberpatch panel system 100 may include a housing 110 and a patch panel 120.Housing 110 may be constructed of a rigid material, such as plastic ormetal, to support and protect the components of fiber patch panel system100. In one implementation, housing 110 may be mounted on a wall in theorientation shown in FIG. 1. With the architecture, as described herein,housing 110 can have a horizontal length that is approximately one-thirdof the horizontal length of existing fiber patch panel systems, whileproviding more optical fiber connections.

Housing 110 may include a door 112 that may provide access to theinterior of housing 110. Door 112 may include a handle or knob 114 tofacilitate opening of door 112. Door 112 may also include a lock 116 torestrict access to the interior of housing 110 to only authorizedpeople.

Housing 110 may include a number of slots 118 through which opticalfibers can pass from outside of housing 110 to inside of housing 110,and vice versa. While slots 118 are shown in FIG. 1 as being located atthe top left and bottom right portions of the sides of housing 110,slots 118 can be located at other locations of housing 110. For example,slots 118 can be located at both the top and bottom portions of bothsides of housing 110 to provide flexibility in the feeding of theoptical fibers into and out of housing 110. Alternatively, oradditionally, slots 118 can be located at both the top and bottomportions of a single side of housing 110. Alternatively, oradditionally, slots 118 can be located elsewhere on one or more sides ofhousing 110. Alternatively, or additionally, slots 118 can be located onthe top and/or bottom of housing 110.

Patch panel 120 may securely attach to housing 110. Patch panel 120 mayfacilitate the connection of the optical fibers. FIG. 2 is an exemplarydiagram of a front view of patch panel 120. Patch panel 120 may includea connection plate 210 and a matrix (e.g., a two dimensional array) offiber connectors 220. While a certain number and arrangement of fiberconnectors 220 are shown in FIG. 2, there may be a different numberand/or arrangement of fiber connectors 220 in other implementations. Tomanage fiber bending and facilitate access to fiber connectors 220,fiber connectors 220 may be arranged in a staggered pattern onconnection plate 210.

Optical fibers are very sensitive to bending. As the bending diameter ofan optical fiber decreases, the power loss for the optical fiberincreases. An increase in power loss may cause degradation in thequality of the signal transmitted on the optical fiber (e.g., video ordata signal). For example, an optical fiber may be able to tolerate abending diameter of 50 to 30 millimeters without much power loss. If thebending diameter becomes 20 millimeters (or even 10 to 5 millimeters),then the power loss may cause the signal quality to degradesignificantly. Fiber connectors 220 may be arranged on connection plate210, as shown in FIG. 2, to manage the bending of the optical fibers andkeep such bending at a tolerable bending diameter.

Connection plate 210 may securely hold fiber connectors 220. FIG. 3 isan exemplary diagram of a front view of connection plate 210. Connectionplate 210 may be formed of a rigid material, such as plastic or metal.Connection plate 210 may include a number of slot pairs 310. Each slotpair 310 may include a pair of through-holes that may facilitate seatingof fiber connectors 220. While a particular number and arrangement ofslot pairs 310 are shown in FIG. 3, the number and arrangement of slotpairs 310 may differ in other implementations.

Returning to FIG. 2, fiber connectors 220 may be seated on connectionplate 210. Each fiber connector 220 may mate two optical fibers in avertical direction. As shown in FIG. 2, in one implementation, a fiberconnector 220 may receive an optical fiber from a top side of connectionplate 210 and may receive an optical fiber from a bottom side ofconnection plate 210.

FIGS. 4A and 4B are exemplary diagrams of a fiber connector 220. FIG. 4Ashows fiber connector 220 from a disassembled state, and FIG. 4B showsfiber connector 220 in an assembled state. While FIGS. 4A and 4B show aparticular architecture for fiber connector 220, fiber connector 220 mayinclude a different arrangement of elements in another implementation.

As shown in FIG. 4A, fiber connector 220 may include connector housing410 and handlers 420 and 430. Connector housing 410 and handlers 420 and430 may be formed of at least a semi-rigid material, such as plastic orrubber.

Connector housing 410 may include a port 412 to receive an opticalfiber. Connector housing 410 may include a corresponding port (not shownin FIG. 4A) on the opposite side of connector housing 410 to receiveanother optical fiber. The pair of ports may be used to connect (mate)two optical fibers together. Connector housing 410 may also include apair of pin holes 414 and 416. Each of pin holes 414 and 416 may includea hole that is capable of receiving a joint pin or the like.

Handler 420 may include a tip 422, a spring 424, and a pin hole 426. Tip422 may be shaped to be inserted into a slot of a slot pair 310 ofconnection plate 210 and securely hold fiber connector 220 againstconnection plate 210 if fiber connector 220 is seated. As shown in FIG.4A, tip 422 may include an angular protrusion portion. In anotherimplementation, tip 422 may be differently shaped.

Spring 424 may include a flexible, elastic material that is capable ofstoring mechanical energy. Pin hole 426 may include a hole that isshaped to mate with pin hole 414 of connector housing 410. Pin holes 414and 426 may be fastened together via a joint pin or the like. The jointpin may rotatably connect handler 420 to connector housing 410.

Handler 430 may include a tip 432, a spring 434, and a pin hole 436. Tip432 may be shaped to be inserted into a slot of a slot pair 310 ofconnection plate 210 and securely hold fiber connector 220 againstconnection plate 210 when fiber connector 220 is seated. As shown inFIG. 4A, tip 432 may include an angular protrusion portion. In anotherimplementation, tip 432 may be differently shaped.

Spring 434 may include a flexible, elastic material that is capable ofstoring mechanical energy. Pin hole 436 may include a hole that isshaped to mate with pin hole 416 of connector housing 410. Pin holes 416and 436 may be fastened together via a joint pin or the like. The jointpin may rotatably connect handler 430 to connector housing 410.

As shown in FIG. 4B, when connector housing 410, handler 420, andhandler 430 are fastened together, springs 424 and 434 may exert a forceagainst connector housing 410 to push the left hand side of fiberconnector 220 outward and the right hand side of fiber connector 220inward, similar to a wooden clothespin. The terms “left hand side” and“right hand side” are intended to be relative to the orientation offiber connector 220 shown in the figures.

FIG. 5 is an exemplary diagram of a front view of fiber connector 220.The front view shows the manner in which fiber connector 220 may bepositioned if seated on connection plate 210. As shown in FIG. 5, twooptical fibers may connect to connector housing 410 in a verticaldirection. With such an arrangement, fiber connector 220 may have a lowprofile if seated on connection plate 210. Unlike a horizontalconnection where gravity causes the optical fibers to bend toward theground, no such bending occurs in a vertical connection.

FIGS. 6A and 6B are exemplary diagrams illustrating the seating of fiberconnector 220 on connection plate 210. As shown in FIG. 6A, a user maypress the left hand side of handlers 420 and 430 together. This maycause the right hand side of handlers 420 and 430 to separate. The usermay then insert the right hand side of handlers 420 and 430 into a slotpair 310 of connection plate 210.

As shown in FIG. 6B, the user may insert the right hand side of handlers420 and 430 until tips 422 and 432 fully pass through connection plate210. The user may then release the left hand side of handlers 420 and430. Springs 424 and 434 may exert a force against connector housing 410to push the left hand side of fiber connector 220 outward and the righthand side of fiber connector 220 inward, thereby securely seating fiberconnector 220 to connection plate 210 via the through-holes of slot pair310. The angular protrusion portions of tips 422 and 432 may preventfiber connector 220 from becoming unseated from connection plate 210.

Fiber connector 220 may, thus, permit easy access to the optical fibersand permit both ends of the optical fibers to be cleaned. For example, auser may simply press the left hand side of handlers 420 and 430together. This may cause the right hand side of handlers 420 and 430 toseparate. The user may then remove the right hand side of handlers 420and 430 from a slot pair 310 of connection plate 210 without disturbingany of the other fiber connectors 220. The user may then remove theoptical fibers from connector housing 410 and clean them. The user mayre-insert the cleaned optical fibers into connector housing 410 andre-seat fiber connector 220 to connection plate 210, as described above.

FIG. 7 is an exemplary diagram of a scaleable fiber patch panel system700. Fiber patch panel system 700 may include a housing 110 thatincludes a door 112 and a number of slots 118, as described above withregard to fiber patch panel system 100 of FIG. 1. Unlike fiber patchpanel system 100, however, fiber patch panel system 700 may include anumber of patch panels 710-1, 710-2, . . . , 710-N (where N>1)(collectively referred to as “patch panels 710”). Each of patch panels710 may be similar to patch panel 120. For example, each of patch panels710 may include a connection plate 210 and a set of fiber connectors220.

Patch panels 710 may be rotatably connected to housing 110 via a set ofhinges 720. A hinge 720 may include any mechanical mechanism thatpermits a patch panel 710 to fixedly attach to housing 110 whilepermitting patch panel 710 to rotate toward door 112 (“open position”)and/or away from door 112 (“closed position”). For example, patch panel710-1 may rotate outwards (toward door 112) exposing patch panel 710-2;patch panel 710-2 may rotate outwards exposing patch panel 710-3; and soforth. Each of patch panels 710 may include a mechanism to permit a userto grab and rotate patch panel 710, such as a handle, an opening, or thelike. In one implementation, the last patch panel (i.e., patch panel710-N) may not be rotatably connected to housing 110 and need notinclude a hinge 720.

Patch panels 710 and/or housing 110 may include a stabilizing mechanism730 (e.g., one or more stoppers and/or magnets) to secure patch panels710 at the closed position within housing 110. In one implementation,the last patch panel (i.e., patch panel 710-N) may not include astabilizing mechanism 730.

Fiber patch panel system 700 may be scaleable in the sense that as manylayers of patch panels 710 may be included within housing 110 as needed.Each additional patch panel 710 may add a number of fiber connectors 220and, thus, a number of potential fiber optic connections.

FIG. 8 is an exemplary diagram of a fiber patch panel system 800 thatincludes a splice tray or drawer (referred to as a “splice tray/drawer”810). Fiber patch panel system 800 may include housing 110 and patchpanel 120/710, as described above with regard to fiber patch panelsystem 100 of FIG. 1 or fiber patch panel system 700 of FIG. 7. In thiscase, however, patch panel 120/710 may occupy a vertical space less thanthe vertical space of housing 110 to leave an area for splicetray/drawer 810. Splice tray/drawer 810 may be used to hold one or morepairs of spliced fibers. Splice tray/drawer 810 may be inserted intohousing 110 to reside on a bottom (or floor) of housing 110. This maymake it easy to install and remove splice tray/drawer 810 as necessary.In another implementation, multiple splice trays or drawers 810 may beused within the bottom area of housing 110.

Implementations described herein may provide an arrangement for a fiberpatch panel system that conserves horizontal space, is scaleable,manages fiber bending, provides easy access to optical fibers forinsertion, removal, and/or cleaning, and/or permits easy installationand removal of a splice tray or drawer.

The foregoing description provides illustration and description, but isnot intended to be exhaustive or to limit the invention to the preciseform disclosed. Modifications and variations are possible in light ofthe above teachings or may be acquired from practice of the invention.

No element, act, or instruction used in the present application shouldbe construed as critical or essential to the invention unless explicitlydescribed as such. Also, as used herein, the article “a” is intended toinclude one or more items. Where only one item is intended, the term“tone” or similar language is used. Further, the phrase “based on” isintended to mean “based, at least in part, on” unless explicitly statedotherwise.

1. A system, comprising: a housing; and a patch panel located within thehousing, the patch panel comprising: a connection plate, and a matrix offiber connectors connected to the connection plate and arranged toreceive optical fibers in a vertical direction.
 2. The system of claim1, wherein the connection plate includes a matrix of slot pairs, each ofthe slot pairs including two through-holes.
 3. The system of claim 2,wherein one of the fiber connectors includes a portion to be insertedthrough the connection plate via the two through-holes.
 4. The system ofclaim 1, wherein one of the fiber connectors includes: a connectorhousing to mate two optical fibers, a first handler connected to a firstside of the connector housing, and a second handler connected to asecond side of the connector housing.
 5. The system of claim 4, whereinthe one of the fiber connectors further includes: a first springassociated with the first handler to apply force to the first side ofthe connector housing, and a second spring associated with the secondhandler to apply force to the second side of the connector housing. 6.The system of claim 4, wherein each of the first handler and the secondhandler includes: a tip to be inserted through the connection plate andsecurely seat the one of the fiber connectors to the connection plate.7. The system of claim 1, wherein the patch panel includes a pluralityof patch panels.
 8. The system of claim 7, wherein a first one of thepatch panels rotatably connects to the housing, the first patch panelbeing capable of being rotated to a first position that conceals asecond one of the patch panels, and the first patch panel being capableof being rotated to a second position that exposes the second patchpanel.
 9. The system of claim 1, wherein the patch panel has a verticallength that is smaller than a vertical length of the housing to create afree space in the housing.
 10. The system of claim 1, furthercomprising: a splice tray or drawer to occupy the free space in thehousing.
 11. A patch panel, comprising: a connection plate; and a matrixof fiber connectors connected to the connection plate and arranged toreceive optical fibers in a vertical direction.
 12. The patch panel ofclaim 11, wherein the connection plate includes a matrix of slot pairs,each of the slot pairs including two through-holes.
 13. The patch panelof claim 12, wherein one of the fiber connectors includes a portion tobe inserted through the connection plate via the two through-holes. 14.The patch panel of claim 11, wherein one of the fiber connectorsincludes: a connector housing to mate two optical fibers, a firsthandler connected to a first side of the connector housing, and a secondhandler connected to a second side of the connector housing.
 15. Thepatch panel of claim 14, wherein the one of the fiber connectors furtherincludes: a first spring associated with the first handler to applyforce to the first side of the connector housing, and a second springassociated with the second handler to apply force to the second side ofthe connector housing.
 16. The patch panel of claim 14, wherein each ofthe first handler and the second handler includes: a tip to be insertedthrough the connection plate and securely seat the one of the fiberconnectors to the connection plate.
 17. A fiber connector, comprising: aconnector housing to mate two optical fibers; a first handler connectedto a first side of the connector housing; and a second handler connectedto a second, opposite side of the connector housing; the first andsecond handlers connect to the connector housing so that when a firstend of the first and second handlers are pressed together, a second endof the first and second handlers separate apart.
 18. The fiber connectorof claim 17, further comprising: a first spring associated with thefirst handler to apply force to the first side of the connector housing;and a second spring associated with the second handler to apply force tothe second side of the connector housing.
 19. The fiber connector ofclaim 17, wherein each of the first handler and the second handlerincludes: a tip to be inserted through a connection plate and securelyseat the fiber connector to the connection plate.
 20. The fiberconnector of claim 19, wherein the tip includes an angular protrusionportion.
 21. A system, comprising: a housing; and a first patch panelcomprising: a first connection plate rotatably connected to the housing,and a first matrix of first fiber connectors connected to the firstconnection plate and arranged to receive a first set of optical fibersin a vertical direction; and a second patch panel comprising: a secondconnection plate connected to the housing, and a second matrix of secondfiber connectors connected to the second connection plate and arrangedto receive a second set of optical fibers in the vertical direction.